Transcript Document

Welcome to the CLU-IN Internet Seminar
Practical Models to Support Remediation Strategy Decision-Making – Part 2
Sponsored by: U.S. EPA Office of Superfund Remediation and Technology Innovation
Delivered: October 17, 2012, 1:00 PM - 3:00 PM, EDT (17:00-19:00 GMT)
Instructors:
Dr. Ron Falta, Clemson University ([email protected])
Dr. Charles Newell, GSI Environmental, Inc. ([email protected])
Dr. Shahla Farhat, GSI Environmental, Inc. ([email protected])
Dr. Brian Looney, Savannah River National Laboratory ([email protected])
Karen Vangelas, Savannah River National Laboratory ([email protected])
Moderator:
Jean Balent, U.S. EPA, Technology Innovation and Field Services Division ([email protected])
1
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3
Practical Models to Support
Remediation Strategy
Decision-Making
Ronald W. Falta, Ph.D
Brian Looney, Ph.D
Charles J. Newell, Ph.D, P.E.
Karen Vangelas
Shahla K. Farhat, Ph.D
Module 2 - October 2012
4
Seminar Disclaimer
• The purpose of this presentation is to
stimulate thought and discussion.
• Nothing in this presentation is
intended to supersede or contravene
the National Contingency Plan
5
Continuum of Tools Available to
Support Environmental Cleanup
Input
Tools
Hand Calculations
Limited
A strong chloroethene source in a
A strong chloroethene
source in a setting
till-over-bedded-sedimentary-rock
hydrogeologic
till-over-bedded-sedimentary-rock
hydrogeologic
with
A strong
chloroethene
source in asetting
A strong
source in a setting
with submerged
atill-over-bedded-sedimentary-rock
methanogenic geochemical
environment.
hydrogeologic
Simple,geochemical
faster with
flow hydrogeologic
a methanogenic
environment. setting
with environment.
a methanogenic geochemical
An anaerobic geochemical environment.
Site Data
Taxonomic Screening
(Scenarios, scoring)
Site Data;
Simplifying
assumptions
“Simple” Analytical Models
(Biochlor, BioBalance)
Complex;
Site-specific
Numerical Models
(MODFLOW, Tough, RT3D)
 REMChlor, REMFuel 
Output
Basic
Binning /
Screening
Exploratory
or decision
level
Complex
6
INSTRUCTORS:
Ron Falta, Ph.D.
 Professor, Dept. of Environmental Engineering
& Earth Sciences, Clemson University
 Ph.D. Material Science & Mineral Engineering,
U. of California, Berkley
 M.S., B.S. Civil Engineering Auburn University
 Instructor for subsurface remediation,
groundwater modeling, and hydrogeology
classes
 Developer of REMChlor and REMFuel Models
 Author of Numerous technical articles
 Key expertise: Hydrogeology, contaminant
transport/remediation, and multiphase flow in porous media
7
INSTRUCTORS:
Charles J Newell, Ph.D., P.E.
 Vice President, GSI Environmental Inc.
 Diplomate in American Academy of Environmental Engineers
 NGWA Certified Ground Water Professional
 Adjunct Professor, Rice University
 Ph.D. Environmental Engineering, Rice Univ.
 Co-Author 2 environmental engineering books;
5 environmental decision support software
systems; numerous technical articles
 Expertise: Site characterization, groundwater modeling,
non-aqueous phase liquids, risk assessment, natural attenuation,
bioremediation, software development, long term monitoring,
non-point source studies
8
INSTRUCTORS:
Vangelas, Looney, Farhat
 Karen Vangelas, Savannah River National Lab
 M.S. Environmental Engineering, Penn State
 Groundwater, remediation
 Brian Looney, Savannah River National Lab
 Ph.D. Environmental Engineering, U. of Minnesota
 Vadose zone, remediation, groundwater modeling
 Shahla Farhat, GSI Environmental
 Ph.D. Environmental Engineering, U. of North Carolina
 Decision support tools, remediation, modeling
9
BREAK FOR DISCUSSION OF
HOMEWORK EXERCISE 1
AND
RESPONSES TO
MODULE 1 QUESTIONS
FROM PARTICIPANTS
10
Explanation of How the
Plume
Works in REMChlor
Analytical
model for
source
behavior
Analytical model for
plume response
11
Key Concept 2: Plumes
Key Driver
On-Site
Affected
Soil
Off-Site
• Discharge from
source
Key Processes
Affected Groundwater
• Advection
• Dispersion
• Adsorption
• Degradation
12
Key Material Balance Equations - Plume
Plume equation solved for each species.
Equations are linked through the chemical
reaction terms.
First-Order Decay
reactions
Ci
Ci
 2Ci
 2Ci
 2Ci
R
 v
  x v 2   y v 2   z v 2  rxni
t
x
x
y
z
Retardation
Coefficient
Groundwater
Seepage
Velocity
Longitudinal
Dispersivity
Hydraulic
Conductivity
V=
Ki
ne
Transverse
Dispersivity
Vertical
Dispersivity
Hydraulic
Gradient
Effective Soil
Porosity
13
Groundwater Transport Processes Biodegradation
 Indigenous micro-organisms are capable of
degrading many contaminants.
 Need electron donor and electron acceptor.
 Fuels like benzene serve as electron donor.
Oxygen, nitrate, sulfate, iron are electron
acceptor.
 Chlorinated solvents act as electron acceptor.
Hydrogen/acetate serve as electron donor.
14
REMChlor
Biodegradation
Decay Chain for
Chlorinated
Ethenes
Halorespiration
(Reductive dechlorination)
PCE
λ1λ1
cis-DCE
ethene or ethane
Aerobic Oxidation
by Cometabolism
TCE
λ2λ2
Key footprints
Rapid; occurs under
all anaerobic
conditions
Rapid; occurs
under all anaerobic
conditions
cis-1,2-DCE
λ3λ3
Slower; sulfatereducing and
methanogenic
conditions
VC
λ4λ4
Slower; sulfatereducing and
methanogenic
conditions only
Aerobic Oxidation
by Cometabolism
Direct Aerobic
Oxidation
Aerobic
Oxidation
Aerobic
Oxidation
Ethene
(Adapted from RTDF, 1997)
All these reactions are First Order Decay.
15
Example REMChlor Sequential Reactions
λ2
λ1
PCE
TCE
Rate PCE =
λ3
λ4
DCE
VC
ETH
– λ1 CPCE
Rate TCE = λ1 y1 CPCE – λ2 CTCE
16
Example Results of Sequential Reactions
1.0
0.8
Conc.
0.6
TCE
DCE
0.4
0.2
VC
0
Distance from Source
17
REMChlor Model: Other Features
Example of Three Reaction Zones for Chlorinated Ethenes
Source
cisDCEgCO2
VCgCO2
PCEgTCEgcisDCEgVCgETH
cisDCE g…
VC g…
Plume
Zone 2
Zone 1
Zone 3
:
Deeply Anaerobic
High Decay Rates
Highly Aerobic
(for example,
if air sparging here)
Low or
Background
Decay Rates
18
REMFuel
Simplified
Biodegradation
Decay Chain
for MTBE
Biodegradation
Slow
hydrolysis
MTBE
λ1λ1
Occurs under aerobic conditions
(may need acclimation)
or
more slowly under anaerobic conditions
TBA
Key footprint:
TBA
λ2
Occurs under aerobic conditions
or
more slowly under anaerobic conditions
or
No degradation under deeply anaerobic
(methanogenic) conditions
CO2
All these reactions are First Order Decay.
19
REMFuel Sequential Reactions
λ1
MTBE
Rate MTBE =
λ2
TBA
CO2
– λ1 CMTBE
Rate TBA = λ1 y1 CMTBE – λ2 CTBA
20
REMFuel Model: Other Features
Example Using Two Reaction Zones for MTBE / TBA
Source
MTBEgTBAg…
MTBEgTBAgCO2
Plume
Zone 2
Zone 1
:
Deeply Anaerobic
(Methanogenic)
MTBE degrades but
no TBA degradation
Aerobic
Both MTBE and
TBA degrade
21
McHugh et al., 2012
Maximum Site Concentrations Over Time
California Geotracker Database
(most with some type of remediation)
22
Maximum Site Concentrations Over Time
California Geotracker Database
(most with some type of remediation)
McHugh et al., 2012
23
REM’s Plume Remediation Model
Divide space and time into “reaction zones”, solve the
coupled parent-daughter reactions for chlorinated solvent
degradation in each zone
Example:
Time
2025
Natural
attenuation
Natural
attenuation
Natural
attenuation
Anaerobic
degradation
Aerobic
degradation
Natural
attenuation
Natural
attenuation
Natural
attenuation
Natural
attenuation
2005
1975
0
Each of these
space-time zones
can have a different
decay rate for each
chemical species.
400
700
Distance from source, m
24
Wrap-Up: Describing Your Plume’s
“Space-Time Story” With REMC and F
1.
2.
3.
4.
Both models allows plume to develop for any number of years before
remediation (Neat!) (Very Important).
You can simulate three natural reaction zones.
You can remediate all or part of the plume by increasing degradation
rates for three specific time periods (1 year? 5 years? You pick).
The plume will respond to all of these factors:
natural attenuation processes
+ plume remediation
+ source decay
+ source remediation (eventually!)
25
Agenda

Class Objectives

What Tools are Out There?

What Are the Key Questions?
– Will Source Remediation Meet Site Goals?
– What Will Happen if No Action is Taken?
– Should I Combine Source and Plume Remediation?
– What is the Remediation Time-Frame?
– What is a Reasonable Remediation Objective?
Note: Many of these questions are interrelated!
26
Will Source Remediation Meet Site Goals?
What are the Goals? Two Examples
U.S. EPA DNAPL Challenge (2003)
•
•
•
•
•
•
Reduce potential for DNAPL migration
Reduce long-term management requirements
Enhance natural attenuation
Reduce loading to receptor
Attain MCLs
“Stewardship”
ITRC LNAPL Guidance (2009)
•
•
•
•
Reduce LNAPL to residual saturation range
Terminate/reduce potential LNAPL body migration
Abate/reduce unacceptable soil vapor and/or
dissolved phase concentrations from LNAPL
Aesthetic LNAPL concern Abated (saturation or
(composition)
27
Will Source Remediation Meet Site Goals?
General Characteristics of Sites
Where is the
bulk of the
contaminant
mass?
SOURCE-DOMINATED
Mostly in the NAPL
source zone
MIXED SOURCE/PLUME
Partly in the source
zone and partly in
the dissolved plume
PLUME-DOMINATED
Mostly in the
dissolved plume
What is the nature of
the plume over time?
(assume that plume
is relatively large)
How much
concentration
reduction is needed
(maximum /desired)
Growing
Factor of ten
Stable
Factor of
five hundred
Shrinking
Factor of ten
thousand
28
Applied Environmental Science Philosophy:
Anatomy of an Impacted Site
Facility
Disturbed zone
Characteristics:
Perturbed conditions
(chemistry, Source
NAPL, etc.)
Need:
Eliminate or mitigate
disturbance by active
engineered solution or
improved design
Transition / Baseline zone
Impact zone
Characteristics:
Area with observable and
easily detectable impacts
Need:
Characterization data
to quantify impacts and
mitigation activities,
as needed, to provide
environmental protection
Characteristics:
Area where impacts are
minimal and conditions are
similar to unimpacted settings
Need:
Careful characterization
to provide a baseline for
understanding impacts,
development. Application of
sensitive methods and early
warning tools. Fundamental
science!
29
Diagnosing and Treating a Site
Waste
site
Source Zone
Costs:
$/lb contaminant or $/cu
yd. Removal
examples:
< $50-$100/cu yd or
< $100/lb for chlorinated
solvents
hot spot characterization
reduces cleanup volume
Dilute Plume/Fringe
Primary Groundwater /
Vadose Zone Plume
Costs:
$/treatment volume (gallon/cu ft)
example:
<$0.5-$10 / 1000 gallons
Costs:
Operation and
maintenance costs $/time
mass transfer and flux
characterization needed
zone of capture characterization
needed, optimize extraction to reduce
treatment volume
30
Real World Plume
31
Technology
Examples
Technology
Class
Continuum of Remediation
Technologies/Strategies/Options
32
stable /
shrinking
plume due to
attenuation
and/or
remediation
TIME
Technology
Examples
b) Potential
remedial
technologies
expanding
plume
Technology
Class
TIME
a) Simplified
representations
of a groundwater
plume in
space and time
33
Technology Coupling
• Three types: temporal, spatial, simultaneous
• IDSS team experience most common approaches:
– Intensive technology followed by passive
– Different technology for Source versus Plume
– Any technology followed by MNA
• In past, “opposing” combinations (ISCO then bio)
were thought to be incompatible. This has proven
to not be always the case.
From ITRC Integrated DNAPL Site Strategy training materials
34
Remediation
Technologies
Used at
California
Benzene Sites
Based on
Geotracker
Database
Data: McHugh et al., 2012
N=1323 Sites
35
Multiple Site Performance Studies
(This and next 3 slides apply to chlorinated solvent sites)
Strong point about these studies …
•
•
•
•
•
•
Strong point about these studies…
Independent researchers, careful before/after evaluation
Repeatable, consistent comparison methodology
Describes spectrum of sites
Real data, not anecdotal
Several studies described in peer reviewed papers:
From ITRC Integrated DNAPL Site Strategy training materials
36
Order of Magnitude are Powers of 10
Why Use OoMs for Remediation?
• Hydraulic conductivity is based on OoMs
• VOC concentration is based on OoMs
• Remediation performance (concentration, mass, Md) can be
also evaluated using OoMs ….
• 90% Reduction:
1
OoM reduction
• 99.9% Reduction:
3
OoM reduction
• 70% Reduction:
0.5
OoM reduction
• Example:
• Before concentration 50,000 ug/L
• After concentration
5 ug/L
• Need 4 OoMs (99.99% reduction)
From ITRC Integrated DNAPL Site Strategy training materials
37
OoM: Order of
Magnitude
Average Before Remediation Concentration (mg/L)
Data: McGuire et al. 2006, GWMR
Graphic: J. Loveless, GSI Environmental
Average After Remediation Concentration (mg/L)
59 Sites Before and After Concentrations – OoM Comparison
38
Others Say Use Caution….
■ Not site specific
■ Some lump pilot scale, full scale
■ May not account for intentional shutdowns
(i.e. they stopped when they got 90%
removal)
■ Don’t account for different levels
of design/experience
■ We are a lot
better now….
From ITRC Integrated DNAPL Site Strategy training materials
39
BREAK FOR QUESTIONS
FROM
PARTICIPANTS
40
Will Source Remediation Meet Site Goals?
How to Use REMChlor and REMFuel
1.
Collect input data.
2.
Determine things you don’t know and make best estimate.
3.
Run model and compare results to available data
(such as most recent sampling event).
4.
Adjust model parameters to fit data (plume length
is most common calibration parameter). Typical things
to adjust are parameters in Step 2 above, particularly:
- Initial source concentration
- Source mass
- Biodegradation rate in plume
- Seepage velocity
5.
Run sensitivity analysis (vary several parameters
and see which ones are important).
41
Will Source Remediation Meet Site Goals?
Show Me How It Works
NUMBER
1
REMChlor and the
TCE Plume
t
42
Will Source Remediation Meet Site Goals? Should We Combine Source and Plume Remediation?
REMChlor Case Study: TCE Plume at a
Manufacturing Plant in North Carolina
■ Plant in eastern NC, currently produces Dacron
polyester resin and fibers.
■ TCE contamination of groundwater discovered in the
late 1980’s; ~ stable plume about 1250 ft long (380 m).
■ Release date unknown, but before 1980.
■ Plume is dominated by TCE; small amounts of
cis-1,2-DCE are present and VC is essentially absent.
■ Groundwater velocity is slow, less than
100 ft/yr seepage velocity.
from Liang et al., Ground Water Monitoring and Remediation, Winter, 2012
43
Will Source Remediation Meet Site Goals? Should We Combine Source and Plume Remediation?
REMChlor Case Study: TCE Plume at a
Manufacturing Plant in North Carolina
■ Source zone TCE mass estimated at 300 lbs
(136 kg), source zone concentrations up to
~6,000 ug/L.
■ Source remediation took place in 1999,
consisting of ZVI injection throughout the
suspected source zone. Although source
mass removal was reported as 95%, wells
in the source zone have not seen large
reductions in concentration.
■ A 5 inch thick permeable reactive barrier
(PRB) using ZVI was installed 290 ft
downgradient of the source in 1999.
44
Will Source Remediation
Meet Site Goals?
Should We Combine
Source and
Plume Remediation?
GW Flow Direction
MW-36
MW-57
MW-38
MW-37
PRB Wall
MW-29
MW-58
MW-35
MW-60
MW-59
Source
Area
MW-47
MW-30A
45
Will Source Remediation Meet Site Goals? Should We Combine Source and Plume Remediation?
REMChlor Model Parameters for Transport/Natural Attenuation
Parameter
Value
Comment
Initial Source Conc., Co
6,000 ug/L
Estimated from source wells
Initial Source Mass, Mo
136 kg
From site reports; assume 1967 release date
Source function exponent, Γ
1
Estimated
Source Width, W
8m
From site reports
Source Depth, D
3.5 m
From site reports
Darcy velocity, V
8 m/yr
Calibrated; reports had estimated 1.5 to 4.6 m/yr
Porosity, φ
0.33
From site reports
Retardation Factor, R
2
Estimated
Longitudinal dispersivity, αl
x/20
Calibrated
Transverse dispersivity, αt
x/50
Calibrated
Vertical dispersivity, αv
x/1000
Estimated
TCE decay rate in plume, λ
0.125 yr-1
Calibrated (equal to t1/2 of 5.5 yrs)
46
Will Source Remediation Meet Site Goals? Should We Combine Source and Plume Remediation?
REMChlor Model Parameters
for Source and Plume Remediation
Parameter
Value
Comment
Fraction of source removed
95%
in 1999, X
From site reports
(but large uncertainty)
PRB wall thickness
(after 1999)
0.127m (5")
From site reports
TCE decay rate in PRB
435 yr-1
Estimated from well data
(equal to t1/2 of 14 hours)
PRB
Treatment
Natural
Attenuation
Natural
Attenuation
Natural
Attenuation
2029
Natural
Attenuation
Natural
Attenuation
Time
1999
Natural
Attenuation
Natural
Attenuation
1967
0
89
89.127
Natural
Attenuation
Distance (m)
47
Will Source Remediation Meet Site Goals?
Should We Combine Source and
Plume Remediation?
GW Flow Direction
MW-36
MW-57
Simulated TCE
concentrations
In 1999 prior to
source
remediation
or PRB wall
installation
Contours at
5, 20, 50,100,
200, 500, and
1000 ug/L
MW-38
MW-37
PRB Wall
MW-29
MW-58
MW-35
MW-60
MW-59
Source
Area
MW-47
MW-30A
48
Will Source Remediation Meet Site Goals?
Should We Combine Source and
Plume Remediation?
GW Flow Direction
MW-36
MW-57
Simulated TCE
concentrations
In 2001, 2 years
after source
remediation and
PRB wall
installation
Contours at 5, 20,
50,100, 200, 500,
and 1000 ug/L
MW-38
MW-37
PRB Wall
MW-29
MW-58
MW-35
MW-60
MW-59
Source
Area
MW-47
MW-30A
49
Will Source Remediation Meet Site Goals?
Should We Combine Source and
Plume Remediation?
GW Flow Direction
MW-36
MW-57
Simulated TCE
concentrations
In 2009, 10 years
after source
remediation and
PRB wall
installation
Contours at 5, 20,
50,100, 200, 500,
and 1000 ug/L
MW-38
MW-37
PRB Wall
MW-29
MW-58
MW-35
MW-60
MW-59
Source
Area
MW-47
MW-30A
50
Will Source Remediation Meet Site Goals?
Should We Combine Source and Plume Remediation?
GW Flow Direction
MW-36
MW-57
MW-38
MW-37
PRB Wall
MW-29
MW-58
MW-35
MW-60
MW-59
Source
Area
MW-47
MW-30A
51
REMChlor Key Points
1.
2.
3.
4.
REMChlor allows plume to develop for any number of years before
remediation (Neat!) (Very Important).
You can simulate three natural reaction zones.
You can remediate all or part of the plume by increasing degradation
rates for three specific time periods (1 year? 5 years? You pick).
The plume will respond to all of these factors:
natural attenuation processes
+ plume remediation
+ source decay
+ source remediation (eventually!)
52
Will Source Remediation Meet Site Goals?
Hands-On
Computer Exercise
NUMBER
1
Now You Try Using
REMChlor For a Site
t
Questions answered:
What will happen if no action taken?
Will source remediation meet site goals?
53
300
Will Source Remediation Meet Site Goals?
Case #1
200
Frame 001  27 Apr 2009 
y
400
200 kg release of 1,2-DCA in 1980
100
■ Groundwater pore
velocity is 60 m/yr
■ 1,2-DCA plume
biodegradation
half life is 2 years
■ Plume is stable,
but not shrinking
2000
300
c1:
50 100 200 500 800
0
200
y
■ Initial source
concentration
is 1 mg/L
-100
0
100
200
300
400
500
x
100
c1:
50 100 200 500 800
2008
0
-100
0
100
200
300
400
500
x
54
Will Source Remediation Meet Site Goals?
Case #1
Where is the bulk
of the
contaminant
mass?
What is the nature of
the plume over time?
(assume that plume is
relatively large)
How much
concentration
reduction is needed
(maximum /desired)
Mostly in the DNAPL
source zone
Growing
Factor of ten
Partly in the source
zone and partly in
the dissolved plume
Stable
Factor of five hundred
Mostly in the
dissolved plume
Shrinking
Factor of ten thousand
55
Will Source Remediation Meet Site Goals? What Will Happen if No Action is Taken?
First Step in Analysis
Assess what will happen if no action is taken.
 Run REMChlor without any source or
plume remediation.
 The source still depletes due to water flushing, but
the depletion may be very slow.
 If the natural source depletion rate is fast, then
source remediation may not be needed.
56
Will Source Remediation Meet Site Goals? What Will Happen if No Action is Taken?
Case 1, Part A: Simulate Natural
Attenuation of Source and Plume
CASE 1, Part A
57
Will Source Remediation Meet Site Goals? What Will Happen if No Action is Taken?
300
Case 1, Part A: Natural Attenuation
of Both Source and Plume
y
200
Frame 001  27 Apr 2009 
In 2080, plume is nearly
the same size, and ~74%
of the original DNAPL
source mass remains.
400
100
2008
c1:
50 100 200 500 800
300
0
0
100
200
y
200
-100
300
400
500
x
1
2080
100
c1:
C/C0
50 100 200 500 800
0
0
M/M0
1
-100
0
100
200
300
400
500
x
58
Will Source Remediation Meet Site Goals? What Will Happen if No Action is Taken?
Next Step in Analysis:
Run Source Remediation
■ Try source remediation.
■ We have assumed that we can remove
90% of the source.
■ Model source remediation between
2010 and 2011.
■ Note that we could combine source
and plume remediation, but in this
simulation, we look at source
remediation alone.
59
Will Source Remediation Meet Site Goals? What Will Happen if No Action is Taken?
Case 1, Part B:
Source Remediation Simulation
60
Will Source Remediation Meet Site Goals? What Will Happen if No Action is Taken?
300
Case 1, Part B: REMChlor
Simulation of Source Remediation
200
Frame 001  27 Apr 2009 
y
400
100
Remove 90% of source mass
between 2010 and 2011.
300
c1:
50 100 200 500 800
2008
0
200
Frame 001  27 Apr 2009 
y
400
-100
Mass removed
by remediation
2010 - 2011
0
100
200
300
1
300
400
500
x
100
c1:
50 100 200 500 800
2014
0
200
y
C/C 0
-100
0
100
200
c1:
0
M/M 0
1
300
400
500
x
100
50 100 200 500 800
2024
0
-100
0
100
200
300
400
500
61
Will Source Remediation Meet Site Goals? What Will Happen if No Action is Taken?
Case 1, Part B: REMChlor
Simulation of Source Remediation
Mass discharge profiles in 2008, 2014, and 2080
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Will Source Remediation Meet Site Goals?
It Appears that Source Remediation
Would Permanently Shrink this Plume
■ The plume does not respond instantly to
source remediation.
■ The beneficial effect of source remediation
“washes” downstream until the plume has
readjusted to the reduced contaminant discharge.
■ Source remediation often results in a
detached plume.
■ Unless the source treatment is perfect (100%),
there will still be a plume, but it will be smaller.
■ The degree of plume shrinkage depends not only
on the fraction removed, but also on the amount
of concentration reduction that is needed.
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